Design And Fabrication Of Abrasive Belt Grinder Mechanical Project

October 3, 2016, 9:51 am

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Design And Fabrication Of Abrasive Belt Grinder Mechanical Project 

ABSTRACT

   The Machine we designed and fabricated is used for grinding any shape of object like Circular, Rectangular, and Polygon.  In our project the work abrasive belt is used to grinding the material. The abrasive belt is rotated by the single phase induction motor. Hence our project namely abrasive belt grinder is a Special type of Machine.  According to the type of material to be grind, the grinding tool can be changed.

This project gives details of grinding various shapes and sizes of components.  This machine can be widely applied in almost all type of industries. By varying the pulley sizes I can get a high end speed of over 10,000 rpm if needed. The only change I would make is to have a totally enclosed motor to keep out the grit.

INTRODUCTION

         Our project is design and fabrication of Multi Use abrasive belt Grinder.  It is used to grind the machining surfaces to super Finish and accuracy. It can be used as an external Grinder by fixing the belt grinder attachment on the conveyor roller. The principle parts of this attachment are main body, motor with pulley, bearings, rope pulley and conveyor abrasive belt etc.

Design And Fabrication Of Abrasive Belt Grinder Mechanical Project

WORKING PRINCIPLE

The abrasive belt is used to grind the material. This abrasive belt is rotated by the single phase induction motor. In our project consist of end bearings with bearing cap, roller wheel, shaft, single phase induction motor and abrasive belt. This whole arrangement is fixed on the frame structure where the component rests.  

The roller wheel is mounted on the two end bearings with bearing cap by suitable arrangement. There are two roller wheel is used in our project to rotate the abrasive belt. One side of the roller wheel shaft, one v-pulley is coupled by the suitable arrangement. The single phase induction motor with V-pulley arrangement is used to rotate the abrasive belt through the belt drive mechanism.

ADVANTAGES

1.The machine is compact and rigid in size.

2.Maintenance is less.

3.It can be used on any place of small grinding application

4.By varying the pulley diameter the speed of the abrasive belt to be changed.

DISADVANTAGES

1.The abrasive belt should be changeable one for different material. This process takes more time.

APPLICATIONS

1.Grinding outside the job in any size of body can be done.

2.As the feed is given automatic, 0.8 micron finish may be achieved.

3.By changing the grades of abrasive belt grinding it can be used to grind the carbon steel, Alloy steel and stainless steel etc

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Aircraft Auto Pilot Roll Control System project Report Download

October 4, 2016, 10:13 am

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Aircraft Auto Pilot Roll Control System project Report Download

Abstract

Autopilot is a system of automatic controls which holds the aircraft on any selected magnetic heading. In this project our goal is to control the roll angle of the aircraft in the auto pilot system.

Aircraft is controlled by three main surfaces: 

1) AILERON

 2) RUDDER

 3) ELEVATOR 

The ailerons are important flight control surfaces present on aircraft. They are small hinged portion present on the outboard section of the wing. These surfaces are movable which control the motion of the longitudinal axis known as roll. They are used to produce the rolling movement for an aircraft.

Actuator is the tool which aims the process to offer the output. Hence the Aileron Actuator is the tool that forms the ailerons motions. 

The Gyro or heading indicator can be found in an aircraft to intimate the pilot where he is heading. It functions on gyroscope available with the aircraft horizontal.

Flight dynamics is about the air and space science vehicle orientation which manages in three dimensions. The aircraft roll control consists of components and functions like controller gain, aileron actuator, aircraft dynamics, and gyro.

The auto pilot system decreases the work burden of pilot. The pilot roll control removes the exhaustion to control the aircraft by the pilot. The system is used for auto missiles to manage the roll angle. It enables the aircraft for the control of auto pilot.

On the trailing edge of the vertical stabilizer is the Rudder. This controls the yaw or the left/right sliding movements of the aircraft. On a real aircraft, this is controlled by the foot pedals. When the pilot pushes the left pedal, the rudder deflects left.

Pushing the right pedal causes the rudder to deflect right. The elevator is on the tail of the aircraft, moving the elevator causes the nose of the aircraft to go up or down, allowing the aircraft to climb or descent.. 

Elevators control the up/down motion of aircraft that is called as pitch. When the pilot pulls the stick backward, the elevators go up. Pushing the stick forward causes the elevators to go down.

AERIAL NAVIGATION: STABILIZERS, AILERONS, RUDDERS AND ELEVATORS

Aircraft Auto Pilot Roll Control System

The tail of the airplane has two types of small wings, called the horizontal and vertical

stabilizers. A pilot uses these surfaces to control the direction of the plane. Both types of stabilizer are symmetrical airfoils, and both have large flaps to alter airflow.

On the horizontal tail wing, these flaps are called elevators as they enable the plane to go up and down through the air. The flaps change the horizontal stabilizer's angle of attack, and the resulting lift either raises the rear of the aircraft (pointing the nose down) or lowers it (pointing the nose skyward).

Meanwhile, the vertical tail wing features a flap known as a rudder. Just like its nautical counterpart on a boat, this key part enables the plane to turn left or right and works along the same principle. 

Finally, we come to the ailerons, horizontal flaps located near the end of an airplane's wings. These flaps allow one wing to generate more lift than the other, resulting in a rolling motion that allows the plane to bank left or right. Ailerons usually work in opposition. As the right aileron deflects upward, the left deflects downward, and vice versa. Some larger aircraft, such as airliners, also achieve this maneuver via deplorable plates called spoilers that raise up from the top center of the wing.

By manipulating these varied wing flaps, a pilot maneuvers the aircraft through the sky. They represent the basics behind everything from a new pilot's first flight to high-speed dogfights and supersonic, hemisphere-spanning jaunts.

Block Diagram Of ROLL Angle control of AUTOPILOT

Block Diagram Of ROLL Angle control of AUTOPILOT

The aircraft roll control provides the components and functions including:

1. Controller gain
2. Aileron actuator
3. Aircraft dynamics
4. Gyro 

Advantages:

1. Auto pilot system reduce the work strain of pilot..
2. Auto pilot roll controlling reduces the fatigue  of controlling the aircraft in flight by the pilot.

Applications

1. It is used in the auto missiles to control the roll angle..
2. It can be used in almost every aircraft for auto pilot controlling..

Conclusion:

 Aircraft is controlled with the help of three important surfaces. They are aileron, rudder, and elevator. The project is build for the purpose that allows the pilot to monitor the aircraft by all parts of flight.

DOWNLOAD :

1) Aircraft Auto Pilot Roll Control System project /SEMINAR Report Download

2) Aircraft Auto Pilot Roll Control System project/ SEMINAR PPT Download

Fabrication of Brass screw threading and cutting machine

October 11, 2016, 9:53 am

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Fabrication of Brass screw threading and cutting machine

SYNOPSIS

Mechanical engineering without production and manufacturing is meaningless and inseparable. Production and manufacturing process deals with conversion of raw materials inputs to finished products as per required dimensions specifications and efficiently using recent technology

The figure shows the block diagram of brass screw Automatic Threading machine. Works on external Die principle. job is located in a chuck, in which a spindle is connected with the motor, the die is hold on a movable fixture which has a degree of freedom in single axis only, when a rod is entered into die in slow speed automatically threading operation will perform then when a thread is done for a stipulated length the machine will be reverse back automatically and thread is released

 

The control functions are programmed and stored in Control unit.  It consists of Set switches, LCD display; relay driver section, AC motor and main part of Control unit.

Control unit is a general-purpose device and is used for control purpose using a fixed program that is stored in ROM.  Many instructions are coupled with pins of the integrated package, the pins are programmable that is capable of having different functions depending on the wishes of programmerIn Control unit based threading machine, the control functions are stored as program in Control unit.  If we can press the set switches, the number of inches to be thread in the MC, the threading will be performed. The setting value is displayed in the LCD display section.

When the program is executed, the signals from the MC are sent to relay driver and relay.  The threading inches will be coupled to the AC motor.  The mechanical action (corresponding to the threading which gets performed), is done in the threading machine.

In this way we can automatically or manual control to the threading machine using Control unit.

Fabrication of Brass screw threading and cutting machine

Advantage:

1) Accuracy is high.

2) Production time is less.

3) Easy to operate.

Disadvantages:

1) Capacity of the machine depends on motor.

What Is Mechanical Engineering | Career , Salary ,Skill Needed

October 11, 2016, 10:42 am

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What Is Mechanical Engineering | Career , Salary ,Skill Needed , Colleges 

What Is Mechanical Engineering

Mechanical engineering is the discipline that applies the principles of engineering, physics, and materials science for the design, analysis, manufacturing, and maintenance of mechanical systems.It is the branch of engineering that involves the design, production, and operation of machinery.It is one of the oldest and broadest of the engineering disciplines.

The mechanical engineering field requires an understanding of core areas including mechanics, kinematics, thermodynamics, materials science, structural analysis, and electricity.Mechanical engineers use these core principles along with tools like computer-aided design, and product lifecycle management to design and analyze manufacturing plants, industrial equipment and machinery, heating and cooling systems, transport systems, aircraft, watercraft, robotics, medical devices, weapons, and others.

Technically, mechanical engineering is the application of the principles and problem-solving techniques of engineering from design to manufacturing to the marketplace for any object. Mechanical engineers analyze their work using the principles of motion, energy, and force — ensuring that designs function safely, efficiently, and reliably, all at a competitive cost.

Mechanical engineers make a difference. That’s because mechanical engineering careers center on creating technologies to meet human needs. Virtually every product or service in modern life has probably been touched in some way by a mechanical engineer to help humankind. 

Mechanical Engineering

What do mechanical engineers do? / What are the duties of an engineer?

Mechanical engineering combines creativity, knowledge and analytical tools to complete the difficult task of shaping an idea into reality.

This transformation happens at the personal scale, affecting human lives on a level we can reach out and touch like robotic prostheses. It happens on the local scale, affecting people in community-level spaces, like with agile interconnected microgrids. And it happens on bigger scales, like with advanced power systems, through engineering that operates nationwide or across the globe. 

Mechanical engineers have an enormous range of opportunity and their education mirrors this breadth of subjects. Students concentrate on one area while strengthening analytical and problem-solving skills applicable to any engineering situation. 

Mechanical Engineering Logo

Disciplines within mechanical engineering include but are not limited to:

1. Acoustics
2. Aerospace
3. Automation
4. Automotive
5. Autonomous Systems
6. Biotechnology
7. Composites
8. Computer Aided Design (CAD)
9. Control Systems
10. Cyber security
11. Design
12. Energy
13. Ergonomics
14. Human health
15. Manufacturing and additive manufacturing
16. Mechanics
17. Nanotechnology
18. Production planning
19. Robotics
20. Structural analysis

Technology itself has also shaped how mechanical engineers work and the suite of tools has grown quite powerful in recent decades. Computer-aided engineering (CAE) is an umbrella term that covers everything from typical CAD techniques to computer-aided manufacturing to computer-aided engineering, involvingfinite element analysis (FEA) and computational fluid dynamics (CFD). These tools and others have further broadened the horizons of mechanical engineering.

What careers are there in mechanical engineering?

Society depends on mechanical engineering. The need for this expertise is great in so many fields, and as such, there is no real limit for the freshly minted mechanical engineer. Jobs are always in demand, particularly in the automotive, aerospace, electronics, biotechnology, and energy industries. 

Here are a handful of mechanical engineering fields.

In statics, research focuses on how forces are transmitted to and throughout a structure. Once a system is in motion, mechanical engineers look at dynamics, or what velocities, accelerations and resulting forces come into play. Kinematics then examines how a mechanism behaves as it moves through its range of motion. 

Materials science delves into determining the best materials for different applications. A part of that is materials strength — testing support loads, stiffness, brittleness and other properties — which is essential for many construction, automobile, and medical materials. 

How energy gets converted into useful power is the heart of thermodynamics, as well as determining what energy is lost in the process. One specific kind of energy, heat transfer, is crucial in many applications and requires gathering and analyzing temperature data and distributions. 

Fluid mechanics, which also has a variety of applications, looks at many properties including pressure drops from fluid flow and aerodynamic drag forces.

Manufacturingis an important step in mechanical engineering. Within the field, researchers investigate the best processes to make manufacturing more efficient. Laboratory methods focus on improving how to measure both thermal and mechanical engineering products and processes. Likewise, machine design develops equipment-scale processes while electrical engineering focuses on circuitry. All this equipment produces vibrations, another field of mechanical engineering, in which researchers study how to predict and control vibrations.   

Engineering economics makes mechanical designs relevant and usable in the real world by estimating manufacturing and life cycle costs of materials, designs, and other engineered products. 

How much do mechanical engineers earn?

Like careers in many other engineering fields, mechanical engineers are well paid. Compared to other fields, mechanical engineers earn well above average throughout each stage of their careers. According to salary.com, the median starting salary for a Mechanical Engineer I in the United States is just under $63,000, with the top ten percent earning close to $75,000.

Effects of Common Alloying Elements in Steel

October 11, 2016, 11:32 am

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Effects of Common Alloying Elements in Steel

By definition, steel is a combination of iron and carbon. Steel is alloyed with various elements to improve physical properties and to produce special properties such as resistance to corrosion or heat. Specific effects of the addition of such elements are outlined below:

Effects of Common Alloying Elements in Steel

Manganese – strength and hardness; decreases ductility and weldability; effects hardenability of steel.

Phosphorus –increases strength and hardness and decreases ductility and notch impact toughness of steel.

Sulfur decreases ductility and notch impact toughness Weldability decreases. Found in the form of sulfide inclusions.

Silicon – one of the principal deoxidizers used in steel making. In low-carbon steels, silicon is generally detrimental to surface quality.

Copper – detrimental to hot-working steels; beneficial to corrosion resistance (Cu>0.20%)

Nickel - ferrite strengthener; increases the hardenability and impact strength of steels.

Molybdenum increases the hardenability; enhances the creep resistance of low-alloy steels

Carbon (C)- The most important constituent of steel. It raises tensile strength, hardness, and resistance to wear and abrasion. It lowers ductility, toughness and machinability.

Tantalum (TA)- Used as stabilizing elements in stainless steels. Each has a high affinity for carbon and forms carbides, which are uniformly dispersed throughout the steel. Thus, localized precipitation of carbides at grain boundaries is prevented.

Titanium (TI)- Used as stabilizing elements in stainless steels. Each has a high affinity for carbon and forms carbides, which are uniformly dispersed throughout the steel. Thus, localized precipitation of carbides at grain boundaries is prevented.

Tungsten (W)-Increases strength, wear resistance, hardness and toughness. Tungsten steels have superior hot-working and greater cutting efficiency at elevated temperatures.

Vanadium (V)- Increases strength, hardness, wear resistance and resistance to shock impact. It retards grain growth, permitting higher quenching temperatures. It also enhances the red-hardness properties of high-speed metal cutting tools.

Automatic Pneumatic Clutch and Braking System

October 12, 2016, 10:21 am

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AUTOMATIC PNEUMATIC CLUTCH AND BRAKING SYSTEM-Mechanical Projects 

SYNOPSIS

          The technology of pneumatics has gained tremendous importance in the field of workplace rationalization and automation from old-fashioned timber works and coal mines to modern machine shops and space robots. It is therefore important that technicians and engineers should have a good knowledge of pneumatic system, air operated valves and accessories. The air is compressed in an air compressor and from the compressor plant the flow medium is transmitted to the pneumatic cylinder through a well laid pipe line system. To maintain optimum efficiency of pneumatic system, it is of vital importance that pressure drop between generation and consumption of compressed air is kept very low.

The aim is to design and develop a control system based an intelligent electronically controlled automotive braking system is called“INTELLIGENT REVERSE BRAKING SYSTEM”. Sensor Operated Pneumatic Brake is consists of IR transmitter and Receiver circuit, Control Unit, Pneumatic breaking system. The IR sensor is used to detect the obstacle. There is any obstacle in the path, the IR sensor senses the obstacle and giving the control signal to the breaking system. The pneumatic breaking system is used to break the system.

WORKING OPERATION

The IR TRANSMITTER circuit is to transmitter the Infra-Red rays. If any obstacle is there in a path, the Infra-Red rays reflected. This reflected Infra-Red rays are received by the receiver circuit is called “IR RECEIVER”.

The IR receiver circuit receives the reflected IR rays and giving the control signal to the control circuit. The control circuit is used to activate the solenoid valve. The operating principle of solenoid valve is already explained in the above chapter.

Automatic Pneumatic Clutch and Braking System

APPLICATION

1. For automobile application
2. Industrial application

ADVANTAGES

• Brake cost will be less.
• Free from wear adjustment.
• Less power consumption
• Less skill technicians is sufficient to operate.
• It gives simplified very operation.
• Installation is simplified very much.
• To avoid other burnable interactions viz.… (Diaphragm) is not used.
• Less time and more profit.

DISADVANTAGES

• Additional cost require doing the automation
• Free from wear adjustment

FABRICATION OF UNIVERSAL TAPPING MACHINE MECHANICAL PROJECT

October 14, 2016, 10:50 am

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FABRICATION OF UNIVERSAL TAPPING MACHINE MECHANICAL PROJECT

SYNOPSIS
The aim of our project is to design and fabricate a pneumatically operated tapping machine is called universal tapping machine. This device is operated by compressed air. It consists of the following main parts.
1.Barrel
2.Shaft
3.bearing
4.couplings, etc
A high pressure compressed air is forced on a fan and the fan is made to rotate. This rotation is transmitted to the machining head by a shaft and the required operation (tapping) is carried out. So this pneumatically operated cylindrical tapping machine device is used for various operations with a less amount of investment.

INTRODUCTION:

The project work subject is one, in which actually we are leaning the theoretical concepts in practical way. Also the practical Experience is one of the aims of this subject. For a developing industry these operating performed and the parts or components produced should have its minimum possible production cost, then only the industry runs profitably. There are a number of units having used in industries for various purposes.

DESIGN OF EQUIPMENT AND DRAWING

 PNEUMATIC COMPONENTS AND ITS SPECIFICATION

The universal tapping machine consists of the following components to full fill the requirements of complete operation of the machine.

1. Double acting pneumatic cylinder

2. Solenoid vale

3. Flow control valve

4. Connectors

5. Hoses

WORKING PRINCIPLE

The cylindrical tapping machine device is an air operated device used for many small operations. It is a portable one. Compressed air is the source of Energy for this device. The compressed air is allowed through the nozzle in such a way to rotate to fan. The rotation obtained is utilized for machining. The nozzles are welded to the barrel at an angle to facilitate free rotation. The rpm and Torque of the shaft depends upon the pressure of the air admitted so by varying the pressure the rpm and torque can be varied.

FABRICATION OF UNIVERSAL TAPPING MACHINE MECHANICAL PROJECT

The parts are interred connected by thick tubes. Clamps are used at the connecting parts to prevent leakage. In threaded parts thread seals are used to prevent leakage. Here the compressed air from the compressor firstly enters the control unit. In the control unit the pressure of the air is controlled and sent to the barrel to rotate the fan in any one direction.

MERITS:

The pneumatically operated multi purpose device has many advantages. They are as follows:

•Low cost, so it can be used in small scale industries

•Higher rate and quicker operations.

•A number of operations like (drilling) , screw driving, reaming etc., can be done.

•The nuts and bolts can be tightened to a particular pressure by operating the gate valve placed in the control unit and the pressure gauge.

•Both loosening and tightening is possible .since there is air flow in both directions.

•The weight of the unit is less and can be easily handled.

•Efficient operation. Since if does not require any electricity for running .

DEMERITS:

•while  working , the compressed air produces noise therefore a silencer may be  used.

•High torque can not obtained.

•Load carrying capacity of this unit is not very high.

APPLICATIONS

This cylindrical tapping machine has a numerous applications in various fields. In Industries, this is used in assembly section. The required pressure is set and the operation is carried out. In automobile shops various operations are required frequently. Drilling, boring, reaming, grinding etc. It is also used as a screw for tightening and loosening nuts and bolts. It is used in

1.In automobile workshops

2.In small Scale industries

3.In such places where frequent changes in operations are required

4.In welding shops for grinding

5.For performance operations in huge parts which can not be done in ordinary machines, since it is portable.

CONCLUSION

The project carried out by us made an impressing task in the field of small scale industries. It is very useful for workers to tapping the drilling holes.

This project will reduce the cost involved in the concern. Project has been designed to perform the entire requirement task at the shortest time available. 

DESIGN AND FABRICATION OF ROLLING MACHINE WITH SPLINES

October 15, 2016, 9:37 am

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DESIGN AND FABRICATION OF ROLLING MACHINE WITH SPLINES

ABSTRACT

Rolling is the process in which the metal and alloys are plastically deformed into semi-finished or finished condition, by passing these between circular or contoured rotating cylinder (rolls). the metals is drawn into the opening between the rolls by frictional force s between the metal and the roll surface. In deforming metal between rolls, the workpiece is subjected to high compressive force from the squeezing action of rolls.

In metalworking rolling is a metal forming process in which metal stock is passed through a pair of rolls. Rolling is classified according to the temperature of the metal rolled. If the temperature of the metal is above its recrystallization temperature, then the process is termed as hot rolling. If the temperature of the metal is below its recrystallization temperature, the process is termed as cold rolling. In terms of usage, hot rolling processes more tonnage than any other manufacturing process and cold rolling processes the most tonnage out of all cold working processes.

Project is based on the need for rolling the sheet metal with splines design This design and fabrication purpose of rolling and designing the sheet metal.

See also: DESIGN AND FABRICATION OF SHEET ROLLING MACHINE

 OUR PROJECT HAVE THE FOLLOWING OBJECTIVES:

This rolling machine is used to roll the sheet metals with splines and to improve the strength of the sheet metals. Rolling machine is device which used for rolling the sheet metal. The sheet metals can be easily rolled. Even an unskilled technician can use them,With these features, we sincerely hope that our project serve as a valuable project.  

Definition of Rolling : The process of plastically deforming metal by passing it between rolls. Rolling is the most widely used forming process, which provides high production and close control of final product. The metal is subjected to high compressive stresses as a result of the friction between the rolls and the Rolling process metal surface.

DESIGN PROCEDURE

 A rolling mill basically consists of

1. Rolls

2. Bearings

3. a housing for containing these parts

4. a drive (motor) for applying power to the rolls and controlling the speed.

Design and Fabrication Of Rolling Machine With Splines

FABRICATION OF ROLLING MACHINE

There are few types of fabrication methods are done on this rolling machine.

They are,

1.Drilling

2.Turning

3.Grinding

4.Chamfering

5.Milling

6.Boring

7.Grooving

8.Welding

Finished Product -Sheet After Passing From Rollers

CONCLUSION 

This report deals with the design and fabrication of Rolling machine and the detailed drawing of the component and assembles. The project carried out by us made an impressing task in forming process. It is very useful in sheet metal industries for mass production. 

Download Project Report :

DESIGN AND FABRICATION OF ROLLING MACHINE WITH SPLINES

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DESIGN AND FABRICATION OF TYRE COUPLING-Mechanical Project

October 18, 2016, 10:04 am

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 DESIGN AND FABRICATION OF TYRE COUPLING

A coupling is a device used to connect two shafts together at their ends for the purpose of transmitting power. Couplings do not normally allow disconnection of shafts during operation, however there are torque limiting couplings which can slip or disconnect when some torque limit is exceeded.

The primary purpose of couplings is to join two pieces of rotating equipment while permitting some degree of misalignment or end movement or both. By careful selection, installation and maintenance of couplings, substantial savings can be made in reduced maintenance costs and downtime.

ABSTRACT

                Mild steel or wrought iron shaft are available in lengths varying from 6 to 10 meters, so as to make them handy and easy to transport. More lengthy shafts cannot be manufactured in a correct form to be used for power transmission. In engineering practice shafts of large lengths are required to transmit the torque which can be obtained by joining two or more shafts in order to obtain the required length. The joining of shafts is done by device is called as coupling.

Tyre coupling is used to connect two shafts which are parallel & and it will make up the Miss alignment and withstand the backlash. HIGH MISALIGNMENT TOLERANCE of one degree per end can be tolerated without damage to the drive shaft or connected equipment bearings. Tyre coupling are made from high strength composite materials. It is mainly used in the Automobile Dry Shaft power Transmission.

DESIGN AND FABRICATION OF TYRE COUPLING

REQUIREMENTS OF A GOOD SHAFT COUPLING:

1. It should be easy to connect or disconnect.
2. It should transmit the full power from one shaft to other  shaft without losses.
3. It should hold the shafts in perfect alignment.

4. It should reduce the transmission of shock loads from one shaft to another shaft.

Importance Of Gate 2017 Exam | Benefits Of Gate 2017

October 21, 2016, 10:37 am

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Importance Of Gate 2017 Exam | Benefits Of Gate 2017 

The Graduate Aptitude Test in Engineering (GATE 2017) online examinations will be held on February 4, 5, 11 and 12 next year (2017). Indian Institute of Technology, Roorkee is the organizing institute for the exam. The final schedule of the examination will be displayed on the official website .

Other important details given on the official website:

1) GATE online application processing system (GOAPS) website will open for enrollment, application filling, application submission on September 1, 2016.

2) The last date for submission of online application is October 4, 2016.

3) The last date for request for change in the choice of examination city is November 16, 2016.

4) The date for availability of admit card for printing is January 5, 2017.

5) The results will be announced on March 27, 2017.

The GATE, is an all-India entrance test to screen candidates for their comprehensive understanding of various undergraduate subjects in engineering, technology, architecture and postgraduate level subjects in science.

It is a test for admissions to the MTech, ME courses and direct PhD at the Indian Institutes of Technology (IITs), National Institutes of Technology (NITs), other government-funded technical institutions and many private universities and institutes across the country.

Importance Of Gate 2017 Exam | Benefits Of Gate 2017

Importance Of GATE SCORE:

The GATE score of a candidate reflects the relative performance level of a candidate. The score is used for admissions to various post-graduate education programs (e.g. Master of Engineering, Master of Technology, Doctor of Philosophy) in Indian higher education institutes, with financial assistance provided by MHRD and other government agencies. Recently, GATE scores are also being used by several Indian public sector undertakings (i.e., government-owned companies) for recruiting graduate engineers in entry-level positions. It is one of the most competitive examinations in India.

Benefits Of Gate 2017 

GATE is an exam which opens up an ocean of possibilities. And believe me, it's not that tough either. 

The possibilities after GATE are :

• M.Tech. : the most conventional future of GATE qualified candidates. M.Tech. from IITs and a few good NITs actually give you deeper understanding of the subject. They will make you love (or hate?) the subject more than you did in your engineering. Moreover, a masters from a good college increases your chances of being selected for PhD at an even better college, in India or abroad.
• M.E. / M.S. : mostly similar to the above point.
• PGDM / PGDIE etc :some colleges also shortlist GATE qualified candidates for technomanagerial courses, NITIE Mumbai being a big name in that list.
• PSU's : the most famous option in recent times. After PSUs started recruiting through GATE, the number of applicants increased substantially. Stable job, fat packages, good standard of living, you got everything.
• A better degree than most engineers (who prefer not to go for masters) implies a few extra jobs for which you are eligible, but they are not.
• A few colleges in Singapore and Germany also consider you for M.S. if you have a decent GATE score. However this option is not usually that talked about, and the information available online is insufficient, so you should double check before considering this.
• Integrated Ph.D. : some colleges let you do an integrated masters plus doctoral programme, directly after your graduation.
• Jobs in core research fields, that are the perfect for you, if you are interested in exploring and unfolding the unseen. Some top notch organizations like BARC, DRDO, ISRO, etc. recruit based on GATE scores.
• Some IIM's also have a few seats for doctoral programmes based on GATE score. Again, this option is not that famous.

Fellowship Programs

The Council of Scientific and Industrial Research (CSIR) introduced the Junior Research Fellowship (JRF) - GATE scheme in 2002 to allow GATE-qualified engineering graduates and GPAT-qualified pharmaceutical graduates to pursue research through suitable Ph.D. programs at CSIRlaboratories.

Stipend and tenure:

The fellowship amount is Rs.25,000 (US$370) per month plus HRA (house rent allowance). In addition, a contingency grant of Rs.20,000 (US$300) per annum (calculated on a pro-rata basis for fraction of a year) is also provided. On completion of 2 years as JRF - GATE, the fellowship upgraded to SRF (Senior Research Fellowship) - GATE and stipend increased to Rs. 28,000 (US$420) per month in the later years, on the basis of assessment of CSIR JRF-NET guidelines.(Source)

DRDO Research:

From this year onwards DRDO is also considering the GATE score for their jobs.

Seminar On BOSE ELECTROMAGNETIC SUSPENSION Report Download

October 23, 2016, 10:05 am

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Seminar On BOSE ELECTROMAGNETIC SUSPENSION Report Download

Abstract: 

Now a day’s comfort and control are two major aspects in field of design and manufacturing. At present condition spring and damper system are used as shock absorber in automobiles. As concerned to comport and control their system are lagging to provide optimum level of performance. With view of increase the comfort and control electromagnetic suspension system introduced to fulfill the requirement of modern days. This seminar intended to explain the resurgence of interest in the suspension system in recent year and outline the significant challenges that lie a head in commercializing suspension system.

Introduction: 

Bose, mention that word and music comes to mind specifically, audio systems for upscale cars, as well as expensive but worth-the-cost systems for the home. Business travelers might even connect that name with noise-canceling headphones that reduce some of the stress of flying. What one doesn't associate with Bose is automobile suspension. By and large, today’s vehicle suspensions use hydraulic dampers (shock absorbers) and springs that are charged with the tasks of absorbing bumps, minimizing the car's body motions while accelerating, braking and turning and keeping the tires in contact with the road surface. Typically, these goals are somewhat at odds with each other. Luxury cars are great at swallowing bumps and providing a plush ride, but handling usually suffers as the car is prone to pitch and dive under acceleration and braking, as well as body lean under cornering .On the other end of the spectrum, stiffly sprung sports cars exhibit minimal body motion as the car is driven aggressively, as cornering is flat, but the ride quality generally suffers. In an ongoing research project that has spanned over 24 years Bose has created a unique electromagnetic suspension system for automobiles that is close to commercial release and is set to replace traditional shocks and springs with electronic actuators. "This is the first time a suspension system is the same for a sports car and for a luxury car", said its creator, Dr Amar Bose, chairman and head of technical design. The result is a ride that is level and bump free over incredibly rough terrain and when the vehicle turns in to corners.

BOSE ELECTROMAGNETIC SUSPENSION

The Bose suspension required significant advancements in four key disciplines: linear electromagnetic motors, power amplifiers, control algorithms, and computation speed. Bose took on the challenge of the first three disciplines and bet on developments that industry would make on the fourth item. The above figure shows the front module of a BOSE suspension. Prototypes of the Bose suspension have been installed in standard production vehicles. These research vehicles have been tested on a wide variety of roads, on tracks, and on durability courses.

Working:

The Bose system uses a linear electromagnetic motor (L.E.M.) at each wheel, 

in lieu of a conventional shock and spring setup. The L.E.M. has the ability to 

extend (as if into a pothole) and retract (as if over a bump) with much greater 

speed than a fluid damper (taking just milliseconds). These lightning-fast reflexes 

and precise movement allow the wheel's motion to be so finely controlled that the 

body of the car remains level, regardless of the goings-on at the wheel level.

Working of Bose Electromagnetic Suspension

The L.E.M. can also counteract the body motion of a car while accelerating, braking and cornering, giving the driver a greater sense of control and passengers less of a need for Dramamine. To further the smooth ride goal, wheel dampers inside each wheel hub smooth out small road imperfections, isolating even those nuances from the passenger compartment. Torsion bars take care of supporting the vehicle, allowing the Bose system to concentrate on optimizing handling and ride dynamics.

A power amplifier supplies the juice to the L.E.M.s. The amplifier is a 

regenerative design that uses the compression force to send power back through 

the amplifier. Thanks to this efficient layout, the Bose suspension uses only about a 

third of the power of a vehicle’s air conditioning system. There are a few other key 

components in the system, such as control algorithms that Bose and his fellow 

brainiacs developed over a few decades of crunching numbers. The target total 

weight for the system is 200 pounds, a goal Bose is confident of attaining.

Features:

• The system draws about two horsepower or one-third the load of a typical air conditioner. While it can exert 50 kilowatts (67 horsepower) of energy to leap a 2x6(plank) covers 49 kilowatts cushioning the landing, with the shocks working like generators.
• Torsion bars and shock units weigh about what two conventional springs and shocks. The controllers and upsized alternator also add some weight, but the total should be less than that of a hydraulic active suspension.
• The system lets a vehicle ride lower at highway speeds to produce less drag and improve handling
• To save power the system is regenerative. When the far side of a pothole helps to push the wheel up almost all the power is recovered. The motors momentarily become generators, shunting the recovered energy to storage, either in the engine battery or in some other device. The system ends up consuming one-third of the energy used by a cars air-conditioner.

Disadvantages: 

Every system has some disadvantages attached to it.Some of the drawbacks can be grouped as below

1.  The main drawback of the system is the cost.As it uses nyodinium magnets which are costly to manufacture.Thus this makes this suspension system costlier than any other suspension available.Thus this system can be seen in only high end cars
2.  The second drawback is ,when this system breakdowns its very difficult and costly affair to repair it .The other system available can be easily be repaired
3. The system is very complex and requires high precision machinery and skilled workers to manufacture

Conclusion:

 For the first time, the Bose suspension demonstrates the ability to combine in one automobile a much smoother ride than any luxury sedan, and less roll and pitch than any sports car. This performance results from a proprietary combination of suspension hardware and control algorithms.

Download: 

Seminar On BOSE ELECTROMAGNETIC SUSPENSION Report Download

5 Things Every Mechanical Student Should Know Before Appearing for IT Interviews

October 24, 2016, 10:01 am

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5 Things Every Mechanical/Civil/ Electrical/Chemical Student Should Know Before Appearing for IT Interviews

Many of my friends are in the final year of their mechanical engineering. What I have been hearing is that there are very less core field companies for mechanical students. Students have also expressed that these core companies require really high aggregates (65% -70%) with a good number of internships. In such a scenario, it becomes very difficult for intelligent but average students to get into these core companies.

In such a competitive scenario, you must think of the backup options that you can choose from. You can either go for management profiles, IT sector, teaching jobs, BPOs(least recommended) and many others.

The second best option left with the mechanical engineering students is IT companies. The number of IT companies coming for recruitments in Engineering colleges is huge. Therefore, this is a great opportunity for engineering students to get into IT companies.

The Multi-National Corporations such as Infosys, Cognizant, HCL, Accenture, TCS recruit around 100+ students per college ever season since they have a very high requirement. Therefore, these companies offer a huge opportunity for mechanical engineering students.

These MNCs love students from mechanical engineering background though IT/CS students are their first preference. The problem with the mechanical students is that they are not updated with the technology which keeps them behind their IT/CS counterparts in getting selected for these companies.

5 Things Every Mechanical Student Should Know Before Appearing for IT Interviews

Here we shall help you with the things that mechanical engineering students should know before appearing for IT interviews on campus.

1. Soft Skills

Believe it or not, the MNCs focus too much on soft skills of the candidates appearing for interviews. Their recruitment  process includes Group Discussion, Telephonic Conversation, Email Writing and some even take Essay Writing. It is, therefore, important that you should be well-versed with your soft skills and especially your English speaking skills.

These companies want the candidates to know how to interact with a client and talk to them efficiently to generate business. Therefore, you must improve your English speaking skills before you appear for these companies. Believe me, if you’re good in English, there are 50% chances of you getting through the interview process. For girls, this is an advantage. 

2. Aptitude and Logical Reasoning Ability 

Being an engineer, every company expects that you should be good in logical reasoning, aptitude and analytical skills. The aptitude test is probably the first parameter on which a company judges you and it is the first filtering round.

There are 700+ students appearing for such MNCs at any given point of time. Hence, these companies need to filter out the candidates. You must focus on improving your logical reasoning and aptitude skills. For basics, a Quantitative Book by R.S. Aggarwal is sufficient. It is more than enough to get through most of the interviews.

See Also:  Aptitude Notes Section 

3. C Programming

Every IT company requires that the interviewees should know at least at least one programming language. The C Programming language is the first choice for every programmer as it is easy to learn and is also in the curriculum of every college. You should be well versed with the concepts of C programming language perfectly. All you need is few websites and a few books to get good in this programming language.

Recommended Websites:

1. CodingAlpha.com

2. geeksforgeeks.org

3. c4learn.com

Recommended Books:

1. ANSI C – E. Balagurusamy

2. Let Us C – Yashwant Kanetkar

These websites will help you to understand C programming and offer various programming codes for free. The books mentioned above are available in every college library. You must refer at least one of them, if not both.

4. Company Research

It is important that you do a research about the company before you appear for an interview. Many times, candidates have no idea of what the company does and what are their businesses. It is important to know who their CEO is, what products does the company sell, and much more such details. You can easily get all these details on the company website and Wikipedia.

The interviewers have two favourite questions:

1. What do you know about our company?

2. Why do you want to join our company?

If you do a proper research about the company, it will help you to formulate answers to the above two questions in a way that will showcase your interest to the interviewer in joining the company. It will also help you to decide which company is suitable for you and which is not.

5. Java Programming

Although it is difficult for mechanical engineers to study different programming languages, but Java is really important. Java is in high demand. People with Java skills are the highest paid employees in MNCs. Java language is the base for many high-end technologies.

If you are good with C programming language, then learning Java is not a big deal. Being a mechanical engineer, the advantage is that the company does not expect you to be a very good programmer. You just need to know the basics.

One week is more than enough to know the basics of Java programming language. You should be able to solve some basic codes in Java which are frequently asked in interviews. Here are some books that you should follow. These books will be available in your libraries.

1. Core Java – Rashmi Kanta Das

2. Let Us Java – Yashwant Kanetkar

Apart from the above-mentioned things, you must know about your own core stream too. I believe that these things mentioned above will help you to ace any IT interview on campus. IT jobs are a very good option after core field jobs for mechanical students. There is a tremendous scope of growth in IT sector.

Author Description:

Tushar Soni is passionate about Programming and Web Development. He writes about Programming and Technology on CodingAlpha. Connect with him on Facebook | LinkedIn| GooglePlus.

What is Air /Fuel ( Fuel /Air ) Ratio- Rich, lean,stoichiometric Mixture Used For Ic Engine

October 25, 2016, 10:39 am

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What is Air /Fuel ( Fuel /Air ) Ratio- Rich, lean,stoichiometric Mixture Used For Ic Engine 

Internal combustion engines burn fuel to create kinetic energy. The burning of fuel is basically the reaction of fuel with oxygen in the air. The amount of oxygen present in the cylinder is the limiting factor for the amount of fuel that can be burnt. If there’s too much fuel present, not all fuel will be burnt and un-burnt fuel will be pushed out through the exhaust valve.

The carburettor controls the fuel/air mixture on a motorbike, and you often hear ‘lean’ and ‘rich’ being used to describe the fuel/air mixture. Let’s look at what effect this ratio has on the engine.

Air/Fuel Ratio Formula

Firstly, there’s a theoretically optimal fuel/air mixture. This is called the stoichiometric mass/volume and it tells you how much air (ie. oxygen) you need to completely burn an amount of fuel. If you have less air than this, the mixture is rich.If you have too much air, the mixture is lean. You can look at it in terms of fuel. Too much fuel gives a rich mixture, too little gives a lean mixture.

For Example: 

15.0:1 = Lean 

14.7:1 = Stoichiometric 

13.0:1 = Rich

The stoichiometric mass is related to the carbon/hydrogren ratio in your fuel. This makes sense, since each carbon atom needs two oxygen atoms to make CO2, and each hydrogren needs on average half an oxygen atom. So you can presumably just add up the number of carbon and hydrogen atoms and do a bit of maths to work out how many oxygen atoms you’re going to need.

If you have the ‘perfect’ amount of oxygen for your petrol you can expect to get about 45 mega-joules of energy for every kilogram of petrol you’ve got. However, engines aren’t perfectly efficient. For a start, to get the maximum amount of work out of the explosion, you’d have to let the gases expand until they’ve cooled down to the surrounding air temperature (look up Carnot cycles somewhere). In a real engine, the gases only get to expand as long as the piston is moving down. When the exhaust port opens, and the piston moves up to put the exhaust gases out, the gases are still hot. That’s why the exhaust pipe gets hot! 

Relationship Between Air Pollution and Stoichiometric ratio

A normal engine has an efficiency of about 20-40%, so it only gets 20-40% of the theoretical maximum amount of energy out of each explosion. The rest of the energy goes to warm up the engine coolant, the exhaust and the engine’s surroundings.

All these hot exhaust gases go out of the cylinder, passing by the exhaust value. This makes the exhaust value pretty hot – up to 300 degrees celcius. Because of this, the exhaust value takes more of a hammering than the inlet valve, since the gases passing into the cylinder are at air temperature.

Apparently, for petrol you get stoichiometric combustion (that’s complete combustion) when you have a fuel/air ratio of 1:15 (that’s 15 parts of air to one part of fuel). You can get more power out of your engine by running a richer mixture of 13:1, but you’ll be producing some partly burned fuel leading to smoky exhaust and a gunky engine. You get maximum thermal efficiency (most energy for a given amount of fuel?) when you have a lean mixture such as 17:1.

Let’s look at what happens when the spark plug fires when you’re running a lean mixture. There’s less fuel molecules to go around, so the flame moves across the cylinder more slowly. This leaves more heat in the cylinder walls and cylinder head, which can lead to overheating. If the fuel/air mixture is very lean, then the flame can still be present when the inlet valve opens, which causes backfire!

If you’ve got a compression ratio of 12:1, with an engine speed of 1500rpm the flame will move across the cylinder at something like 15 meters per second.

As the engine speed increases, there’s less time for the mixture to burn completely. An engine running at 1000rpm spends 0.06 secs in each cycle, which drops to 0.006 secs when it’s running at 10,000rpm. One way to combat this drop in available burning time is to fire the spark plug a bit earlier when the engine is running fast – this is called the spark advance. If you increase the spark advance too much, it can cause knocking. However, if the engine is running fast then there’s less time for reactions to occur on front of the flame front, which tends to decrease the chance of knocking.

Types of Flows in a Pipe /Fluid Mechanics

October 28, 2016, 10:45 am

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Types of Flows in a Pipe /Fluid Mechanics -Basic Of Fluid Mechanics 

Types of Flows in a Pipe - The type of flow of a liquid depends upon the manner in which the particles unite and move. Though there are many types of flows, yet the following are important :

1. Uniform flow: A flow, in which the liquid particles at all sections of a pipe or channel have  the same velocities, is called a uniform flow.

2. Non-uniform flow: A flow, in which the liquid particles at different sections of a pipe or channel have different velocities, is called a non-uniform flow.

See also:Classification of fluids | basic of fluid Mechanics

Types Of Flows -Laminar and Turbulence Flow

3. Streamline flow (Laminar Flow) : A flow, in which each liquid particle has a definite path and the paths of individual particles do not cross each other, is called a streamline flow.

4. Turbulent flow: A flow, in which each liquid particle does not have a definite path and the paths of individual particles also cross each other, is called a turbulent flow.

5. Steady flow: A flow, in which the quantity of liquid flowing per second is constant, is called a steady flow. A steady flow may be uniform or non - uniform.

6. Unsteady flow: A flow, in which the quantity of liquid flowing per second is not constant, is called an unsteady flow.

7. Compressible flow: A flow, in which the volume of a fluid and its density changes during the flow, is called a compressible flow. All the gases are considered to have compressible flow.

8. Incompressible flow: A flow, in which the volume of a fluid and its density does not change during the flow, is called an incompressible flow. All the liquids are considered to have incompressible flow.

9. Rotational flow: A flow, in which the fluid particles also rotate (i.e. have some angular velocity) about their own axes while flowing, is called a rotational flow.

10. Irrotational flow: A flow, in which the fluid particles do not rotate about their own axes and retain their original orientations, is called an irrotational flow.

11. One-dimensional flow: A flow, in which the streamlines of its moving particles are represented by straight line, is called an one-dimensional flow.

12. Two-dimensional flow: A flow, whose streamlines of its moving particles are represented by a curve, is called a two-dimensional flow.

13. Three - dimensional flow: A flow, whose streamlines are represented in space i.e. along the three mutually perpendicular directions, is called a three - dimensional flow.

Design and fabrication of stair climber trolley Mechanical Project

November 4, 2016, 11:25 am

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DESIGN AND FABRICATION OF STAIR CLIMBER TROLLEY

Abstract

This project aims at developing a mechanism for easy transportation of heavy loads over stairs. The need for such a system arises from day-to-day requirements in our society. Devices such as hand trolleys are used to relieve the stress of lifting while on flat ground; however, these devices usually fail when it comes to carrying the load over short fleet of stairs. In the light of this, the project attempts to design a stair climbing hand cart which can carry heavy objects up the stairs with less effort compared to carrying them manually. It also endeavors to study the commercial viability and importance of such a product. Several designs were conceived that would allow a non-industrial hand trolley to travel over stairs, curbs, or uneven terrain while reducing the strain on the

user.

In our project, the trolley is equipped with Tri-Star wheels which enable us to carry load up and down the stairs. It also eases the movement of trolley in-irregular surfaces like holes, bumps, etc.

Design and fabrication of stair climber trolley

HAND TROLLEY

A hand trolley is a small transport device used to move heavy loads from one place to another. It is a very common tool used by a large number of industries that transport physical products. Also called a hand truck or a dolly, the hand trolley is often used by stock persons who arrange and restock

merchandise in retail stores. When used properly, trolleys can protect people from back injuries and other health problems that can result from lifting heavy loads.

Description

A typical hand trolley consists of two small wheels located beneath a load-bearing platform, the hand trolley usually has two handles on its support frame. These handles are used to push, pull and maneuver the device. The handles may extend from the top rear of the frame, or one handle may curve from the back. An empty hand trolley usually stands upright in an L-shape, and products are usually stacked on top of the platform. When the goods are in place, it is tilted backward so that the load is balanced between the platform and the support frame. Especially if heavy or fragile materials are moved, the person operating the trolley should return it to an upright position carefully, to insure

nothing falls off the platform. The front of the frame may be squared off for boxes or curved for drums and barrels. Sometimes, a hand truck also has straps for securing loose freight during transport.

Professional material handlers prefer to use a hand truck when moving stackable items such as boxes, crates or packages. Heavier items are usually stacked on the bottom of the hand truck, with lighter objects saved for the top.

Hand truck users must be careful not to stack it so high that their vision is blocked or the load becomes unstable. Generally, it is safe to load a hand truck to the level of its handles or the top of the frame. The load is then shifted onto the wheels with a backwards lifting motion. The user can maneuver the cargo by steering it left, right or forward.

NEED FOR STAIR CLIMBER TROLLEY

Lifting heavy objects to upper stories or lifting patients to upper levels from the ground are not painless jobs, especially where there are no lifting facilities (elevator, conveyer, etc.). Moreover, most of the buildings are structurally congested and do not have elevators or escalators. This project can

introduce a new option for the transportation of loads over the stairs. The stair climbing hand trolley can play an important role in those areas to lift loads over a short height.

STAIR CLIMBER TROLLEY

The stair-climbing hand truck is designed to reduce liability rather than increase it. Conventional hand trucks work well on flat ground, but their usefulness decreases when it becomes necessary to move an object over an irregular surface. Package deliverymen, for example, often find it necessary to drag loaded hand trucks up short flights of stairs just to reach the front door of a

building. The entire purpose of using a conventional hand truck is to avoid having to lift and carry heavy objects around.

Lifting a hand truck up the stairs defeats the purpose of the device, since the user must provide enough upward force to lift the entire weight of the cart and its contents. Furthermore, the geometry of a hand truck makes it nearly impossible to lift with one's legs, as is the proper form. Considerable strain is placed on the back muscles and the risk of operator injury is sharply increased.

The pulling up of a standard hand truck up the stairs results in a bumpy and jarring motion. This motion may damage the items loaded on the hand truck or cause them to fall off entirely. A hand truck that could climb stairs without requiring the user to lift would improve the safety of moving heavy objects over irregular surfaces.

In our project, we are designing and fabricating normal hand trolleys with Tri-Star wheel in order to enable the trolley to move up or down the stairs.

TRI-STAR WHEEL DESIGN

The Tri-Star wheel was designed in 1967 by Robert and John Forsyth of the Lockheed Aircraft Corporation. They were first developed as a module of the Lockheed Terrastar, a commercially unsuccessful amphibious military vehicle. A Tri-Star wheel functions as an ordinary wheel on flat ground, but has the ability to climb automatically when an impediment to rolling is encountered.

This wheel design consists of three tires, each mounted to a separate shaft. These shafts are located at the vertices of an equilateral triangle. The three shafts are geared to a fourth, central shaft (to which a motor may be attached).

Tri-Star Wheel in Motion

When geared in this quasi-planetary fashion, these triangular sets of wheels can negotiate many types of terrain, including sand and mud; they can also allow a vehicle to climb over small obstructions such as rocks, holes, and stairs. The wheel assembly may be gear-driven, with two wheels in rolling contact with the ground. The third wheel idles at the top until the lower front wheel hits an

obstruction. The obstruction prevents the lower front wheel from moving forward but does not affect the motion of the driving axle. This causes the top wheel to roll forward into position as the new front wheel. This wheel usually lands on top of the obstruction and allows the rest of the assembly to vault over the obstruction. Tri-Star wheel in motion is shown in figure 

APPLICATION OF TRI-STAR WHEEL IN OUR PROJECT

In our project, we are using this Tri-Star wheel arrangement in a hand trolley in the place of normal wheels setup to enable the trolley to climb up and down the stair cases and also to up come small obstacles like holes and bumps on its path.

CONCLUSION

Though this project had some limitations regarding the strength and built of the structure, it can be considered to be a small step forward, as far as Stair Climbing Vehicles are concerned. During the test run of this project, it was realized that it wouldn’t be a bad idea to consider this design for carrying heavy loads up the stairs. This product will be well acclaimed if it can be commercialized to suit the needs. Though the initial cost of the project seemed to be higher but more accurate manufacturing would shorten this. As far the commercial aspects of this product are concerned, if this product can be fully automated and produced at a lower cost the acceptance will be unimaginable. Presently, there are no competitors for such a kind of product in our market.

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Design and fabrication of stair climber trolley Mechanical Project 

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Design and fabrication of helical tube in coil type heat exchanger

November 5, 2016, 8:13 am

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Design and fabrication of helical tube in coil type heat exchanger

Introduction        

A heat exchanger is a device used to heat transfer between two or more fluids for various application including power plants, nuclear reactors, refrigeration & air condition system, automotive industries, heat recovery system, chemical processing and food industries. The various types of heat transfer enhancement techniques are classified into two main categories. Active techniques which require external power for heat transfer augmentation, and passive techniques which not require such external power for enhancement. One of the passive techniques is the use of helically coiled tubes. Several papers studied and indicated that helical coiled tubes are superior to straight tube due to their compactness and increased heat transfer coefficient .Helical coils are used for various processes such as heat exchangers because they can accommodate a large heat transfer area in a small space, with high heat transfer coefficient. The centrifugal forces are acting on the moving fluid due to the curvature of the tube results in the development.

Helical Tube:

                   Helical tubes are universally used in chemical reactors, ocean engineering, heat exchangers, piping system and many other engineering applications. It has been long recognized that heat transfer characteristic of helical tubes is much better than the straight ones because of the occurrence of secondary fluid flow in planes normal to the main flow inside the helical structure .Helical tubes show great performance in heat transfer enhancement, while the uniform curvature of spiral structure is inconvenient in pipe installation in heat exchangers. It has been widely reported in literature that heat transfer rates in helical coils are higher as compared to those in straight tubes. Due to the compact structure and high heat transfer coefficient, helical coil heat exchangers find extensive use in industrial applications such as power generation, nuclear industry, process plants, heat recovery systems, refrigeration, food industry, etc.

Helical Tube

Operational Features :

1. Fully drain-able inner and outer coil.
2. Spiral wound for maximum counter flow efficiency.
3. Spiral wound for maximum parallel flow efficiency.
4. Constant fluid velocity.
5. No dead spots or crevices.
6. Fluids and slurries.
7. Highly resistant to thermal and hydraulic  shock.

Material Used For Exchanger 

• Copper for inner tube
• Copper for outer tube
• SS316 L for fittings and connectors.

Objectives :

• System design and theoretical derivation of dimension of inner tube , outer tube , number of coils for the desired temperature gradient
• Design and fabrication of Helical tube in tube coil heat exchanger with closed coil structure..
• Design and fabrication of Test rig for testing of Helical tube in tube coil heat exchanger
• Testing of Helical tube in tube coil heat exchanger in parallel flow configuration to determine:
•  LMTD
• Capacity ratio
• Effectiveness 
• Testing of Helical tube in tube coil heat exchanger in counter flow configuration to determine:
• LMTD
• Capacity ratio
• Effectiveness.

Components:

1. Helical Coil.
2. Water Tank.
3. Boom (vertical support).
4. Holder Pin.

Design Of Coil:

1. Diameter of inner tube di = 6.4 mm
2. Diameter of outer tube do =12.5 mm
3. Length of tube L= 2.7 m
4. No. of turns of coil N= 7
5. Pitch of coil p= 30
6. Outside dia of Coil De= 150.

Design and fabrication of helical tube in coil type heat exchanger

Application:

1)They are mainly employed in the field of cryogenics for cryogenic separation and liquefaction of air, natural gas processing and liquefaction, production of petrochemicals and large refrigeration systems. The exchangers that are used for cryogenic air separation and LPG fractionation are the largest and most complex units of the plate fin type and a single unit could be of several meters in length. 

2)They are being used mainly in environment control system of the aircraft, avionics and hydraulic oil cooling and fuel heating.

3) In the automobile sector they are used for making the radiators.

Other Applications :

1. Fuel cells

2 . Process heat exchangers.

3 . Heat recovery plants.

4 . Pollution control systems

5 . Fuel processing and conditioning plants.

6 . Ethylene and propylene production plants.

Advantages Of Heat Exchanger:

1. Compactness

2. Effectiveness

3. Temperature control

4. Flexibility

5. True counter flow operation.

Disadvantages Of Heat Exchanger:

1. Limited range of temperature and pressure.

2. Difficulty in cleaning of passages, which limits it application to clean and relatively non- corrosive fluids.

3. Difficulty of repair in case of failure or leakage between passages.

4. Helical tube complicated in design.

Development of Multi Purpose Machine With Scotch Yoke Mechanism

November 6, 2016, 7:53 am

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Development of Multi Purpose Machine With Scotch Yoke Mechanism-Hacksaw, Shaping Machine 

INTRODUCTION

Multi-operation machine as a research area is motivated by questions that arise in industrial manufacturing, production planning, and computer control. Consider a large automotive garage with specialized shops. A car may require the following work, replace exhaust system, align wheels, and tune up. These three tasks may be carried out in any order.However, since the exhaust system, alignment, and tune-up shops are in different buildings, it is impossible to perform two tasks for a car simultaneously. When there are many cars requiring services at the three shops, it is desirable to construct a service schedule that takes the least amount of total time.

See Also:
1) GEAR LESS POWER TRANSMISSION WITH SCOTCH YOKE MECHANISM- PROJECT
2) Double acting Hack saw Machine Operated By Scotch Yoke Mechanism

Development of Multi Purpose Machine With Scotch Yoke Mechanism

Scotch Yoke Mechanism

The Scotch yoke is a mechanism for converting the linear motion of a slider into rotational motion or vice-versa. The piston or other reciprocating part is directly coupled to a sliding yoke with a slot that engages a pin on the rotating part. The shape of the motion of the piston is a pure sine wave over.

Construction

The scotch yoke mechanism is constructed with iron bars. Here the crank is made in some length and the yoke is also made using the same material. It is noted that the minimum length of the yoke should be double the length of the crank. The crank and yoke is connected with a pin. Iron bars are welded to both sides of the yoke to get the reciprocating motion. The yoke with the iron bars is fixed on the display board with the help of c clamp. Now the crank is welded to the end of the shaft of the motor. Now the pin on the crank is connected to the yoke. The pin used to connect yoke and crank is a bolt.

Working principle

When the power is supplied to the 12v Dc motor, shaft and crank attached to the shaft start rotating. As the crank rotates the pin slides inside the yoke and also moves the yoke forward. When-the crank rotates through in clockwise direction the yoke will get a displacement in the forward direction. The maximum displacement will be equal to the length of the crank. When the crank completes the next of rotation the yoke comes back to its initial position. For the next of rotation,yoke moves in the backward direction. When the crank completes a full rotation the yoke moves back 

to the initial position. For a complete rotation of crank the yoke moves through a length equal to double the length of the crank. The displacement of the yoke can be controlled by varying the length of the crank.

Advantages

1. High torque output with a small cylinder size
2. Fewer moving parts
3. Smoother operation
4. Higher percentage of the time spent at top dead center (dwell) improving theoretical engine efficiency of constant volume combustion cycles though actual gains have not been demonstrated.
5. In an engine application, elimination of joint typically served by a wrist pin, and near elimination of piston skirt and cylinder scuffing, as side loading of piston due to sine of connecting rod angle is eliminated.

Disadvantages

• Rapid wear of the slot in the yoke caused by sliding friction and high contact pressures.
• Increased heat loss during combustion due to extended dwell at top dead center offsets any constant volume combustion improvements in real engines.
• Lesser percentage of the time spent at bottom dead center reducing blow down time for two stroke engines, when compared with a conventional piston and crankshaft mechanism.

 Applications

1. This setup is most commonly used in control valve actuator sin high pressure oil and gas pipelines
2. It has been used in various internal combustion engines, such as the Bourke engine, SyTech engine, and many hot air engines and steam engines. 
3. It is also used in multipurpose machines and I.C engines.

DESIGN AND FABRICATION OF WATT AND PORTER GOVERNOR

November 6, 2016, 10:05 am

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DESIGN AND FABRICATION OF WATT AND PORTER GOVERNOR

ABSTRACT

The aim of our project is to develop prototype of a product “watt and porter governor”. The function of the governor is to maintain the speed of an engine within specified limits whenever there is a variation of load. It is a dynamic device done in the field of manufacturing technology. It's rather

inexpensive and can be used in almost all vehicles. The governor generally consists of a sleeve which is attached to a throttle valve. When the sleeve reaches its lowest position, the engine should develop

maximum power. On the sudden removal of load its sleeve should reach the top most position at once. Its sleeve should float at some intermediate position under normal operating conditions.

When the load on an engine increases or decreases, obviously its speed will respectively decrease or increase to the extent of variation of load. This variation of speed has to be controlled by the governor, within small limits of the mean speed. This necessities that when the load increases and consequently the speed decreases, the supply of fuel to one engine has to be increased accordingly, to compensate for the loss of the speed, so as to bring back the speed close to the mean speed. Conversely when the load decreases, and the speed increase, the supply of fuel has to be reduced. This implies that the governor should have its mechanism working in such a way, that the supply of

fuel is automatically regulated according to the load requirement for maintaining approximately a constant speed.

DESIGN AND FABRICATION OF WATT AND PORTER GOVERNOR

INTRODUCTION

A governor, or speed limiter, is a device used to measure and regulate the speed of a machine, such as an engine. A classic example is the centrifugal governor, also known as the watt or fly-ball governor, which uses weights mounted on spring-loaded arms to determine how fast a shaft is spinning, and

then uses proportional control to regulate the shaft speed. Centrifugal governors were used to regulate the distance and pressure between millstones in windmills since the 17th century. Early steam engines

employed a purely reciprocating motion, and were used for pumping water – an application that could tolerate variations in the working speed. It was not until the Scottish engineer James Watt introduced the rotative steam engine, for driving factory machinery, that a constant operating speed became necessary.

Between the years 1775 and 1800, Watt, in partnership with industrialist Matthew Bolton, produced some 500 rotati-ve beam engines. At the heart of these engines was Watt‟s self-designed "conical pendulum" governor: a set of revolving steel balls attached to a vertical spindle by link arms, where the controlling force consists of the weight of the balls.

Building on Watt‟s design was American engineer Willard Gibbs who in 1872 theoretically analyzed Watt‟s conical pendulum governor from a mathematical energy balance perspective. During his graduate school years at Yale University, Gibbs observed that the operation of the device in practice was beset with the disadvantages of sluggishness and a tendency to over correct for the changes in speed it was supposed to control.

CLASSIFICATION

(i) A governor, or speed limiter, is a device used to measure and regulate the speed of a machine, such as an engine. A classic example is the centrifugal governor, also known as the Watt governor, which uses weights mounted on loaded arms to determine how fast a shaft is spinning, and then

uses proportional control to regulate the shaft speed. The watt governor is named after James Watt who used it for steam engines. James Watt designed his first governor in 1788 following a suggestion from his business partner Matthew Boulton. It was a conical pendulum governor and one of the final

series of innovations Watt had employed for steam engines. James Watt never claimed the centrifugal governor to be an invention of his own.

Centrifugal governors were used to regulate the distance and pressure between millstones in windmills since the 17th century. It is therefore a misunderstanding that James Watt is the inventor of this device.

(ii) A giant statue of Watt's governor stands at Smethwick in the English West Midlands. It is known as the fly ball governor.

(iii) Another kind of centrifugal governor consists of a pair of masses on a spindle inside a cylinder, the masses or the cylinder being coated with pads, somewhat like a drum brake. This is used in a spring-loaded record player and a spring-loaded telephone dial to limit the speed.

(iv) The major advantage of the governors is rather inexpensive and highly efficient.

CLASSIFICATION OF GOVERNORS:

The governors may, broadly, be classified as

1. Centrifugal governor

2. Inertia governor

Governors may further be classified as follows:

1. Pendulum type (Watt governor)

2. Loaded type

COMPONENTS

Frame:

A frame is a structural system that supports other components of a physical construction.

Shaft/Spindle:

A spindle is a rotating axis of the machine, which often has a shaft at its heart. The shaft itself is called a spindle, but also, in shop-floor practice, the word often is used metonymically to refer to the entire rotary unit, including not only the shaft itself, but its bearings and anything attached to it.

Motor:

An electric motor converts electrical energy into mechanical energy. Most electric motors operate through interacting magnetic fields and current carrying conductors to generate force, although electrostatic motors use electrostatic forces.

SLEEVE:

The sleeve valve is a type of valve mechanism for piston engines, distinct from the more common poppet valve.

BEARING:

A bearing is a device to allow constrained relative motion between two or more parts, typically rotation or linear movement. Bearings may be classified broadly according to the motions they allow and according to their principle of operation as well as by the directions of applied loads they can

handle.

RULER:

A ruler, sometimes called a rule or line gauge, is an instrument used in geometry, technical drawing, printing and engineering/building to measure distances and/or to rule straight lines.

WATT GOVERNOR

The Watt governor is a simple governor but is not terribly accurate where very fine control of speeds in needed and so was super ceded in many applications by more specialized and accurate governors, however for many agricultural end pumping engines where absolute speed was not essential it survived and can still be seen on numerous preserved engines.

SPECIFICATIONS:

Basic specifications:

(i) Power supply

(ii) 230 V AC, Single phase, Variac.

Materials:

(i) Spindle: Stainless Steel

(ii) Fly balls: Cast Iron

(iii) Arms: Stainless steel

(iv) Frame: Mild steel

Governor Mechanism:

Watt Governor

Principle:

The function of the governor is to regulate the mean speed of an engine, when there are variations in the load .e.g. when the load on an engine increases, its speed decreases therefore it becomes necessary to increases the supply of working fluid .On the other hand, when the load on the engine decreases, its speed increases and thus less working fluid is required. The governor

automatically controls the supply of the working fluid to the engine with the varying load conditions and keeps the mean speed within certain limits.

A little consideration will show ,that when the load increases ,the configuration of the governor changes and a valve is moved to increase the supply of the working fluid ; conversely , when the load decreases , the engine speed increases and the governor decreases the supply of working fluid.

Working:

Probably the most widely used governor in the early days; it is named the watt governor because James Watt applied it to his early beam engines. He did not however invent it as it had been in use on wind and water mills many years before this. A belt or gearing from the engine crankshaft drives the input shaft 'm' causing the bevel gears 'l' to revolve and in turn rotate the vertical shaft

'a'. The bracket 'b' at the top of 'a' supports two arms 'c' which are pivoted at the top, at the end of the arms are two very heavy metal weights 'B' partway along the arms 'c' are fixed two pivoted link arms 'd'which link to a collar 'c' which rotates with them but is able to slide up and down shaft 'a'.

WORKING OF WATT AND PORTER GOVERNOR

The up and down motion of this collar is followed by a pair of pins 'f' which move a bell crank 'g' which is in turn linked to a throttle actuating rod 'I' linked to a throttle or butterfly valve in the supply of steam to the engines cylinder which can allow more or less steam through.

At rest the governor weights are held in the lowest position by gravity, the throttle will be in its most open position. As the engine speed increases these weights rotate faster until centrifugal force exceeds that of gravity and they fly further outwards and as a result of the linkages, upwards, this movement is transmitted to the throttle valve which begins to close. The faster the governor is

driven the further out the weights move and the more the throttle is closed, until the amount of steam it lets through balances the demand and the engine speed stabilizes.

FABRICATION OF PORTER GOVERNOR

Fabrication as an industrial term refers to building metal structures by

cutting, bending and assembling.

The fabrication of porter governor involves:

i. Turning operation in lathe. (spindle)

ii. Threading operation in lathe.( Spindle)

iii. Drilling holes in porter arms, frame and dead weight.

iv. Step turning of sleeve.

v. Cylindrical grinding for good surface finish.

vi. Welding operation. (Frame and Arms).

vii. Gas cutting of frame.

The fabrication of the components is similar to that of the watt governor. As the Dead weight is the only inclusion to watt governor setup.

APPLICATIONS

(i) On aircraft propellers the governor senses shaft rpm, and adjusts or controls the angle of the blades to vary the torque load on the engine. Thus as the aircraft speeds up (as in a dive) or slows (in climb) the RPM is held constant.

(ii) Centrifugal flyweight mechanism driven by the engine is linked to the throttle and works against a spring in a fashion similar to that of the pneumatic governor, resulting in essentially identical operation. 

(iii) Pneumatic governor. However, the centrifugal design is more sensitive to speed changes and hence is better suited to engines that experience large fluctuations in loading.

(iv) Electronic servo motor is linked to the throttle and controlled by an electronic module that senses engine speed by counting electrical pulses emitted by the ignition system or a magnetic pickup. The frequency of these pulses varies directly with engine speed, allowing the control module to apply a proportional voltage to the servo to regulate engine speed. Due to their sensitivity and rapid response to speed changes, electronic governors are often fitted to engine-driven generators designed to power computer hardware, as the generator's output frequency must be held within narrow limits to avoid malfunction.

Download:

DESIGN AND FABRICATION OF WATT AND PORTER GOVERNOR Report Download 

FABRICATION OF PNEUMATIC CONTROLLED RIVETTING AND PUNCHING MACHINE

November 7, 2016, 8:33 am

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FABRICATION OF PNEUMATIC CONTROLLED RIVETING AND PUNCHING MACHINE-MINI PROJECT

ABSTRACT

In our Project work“FABRICATION OF PNEUMATIC CONTROLLED RIVETING AND PUNCHING MACHINE” we used principles of Pneumatic control system in developing this project work., In our project we are having two control switches, when first switch is pressed it works as a Riveting machine and when the second switch is pressed it works as Punching machine. The vibrating mechanism is achieved by reciprocating the double acting cylinders, which controlled by solenoid operated 5/2 way DC valve which is actuated through the control system.

The operating pressure required for this system is 5 to 6 bar. The maintenance required for this system is less than the other systems.

For punching operation, a counter weight is added to the pneumatic cylinder force in order to make the punching operation effectively, and also for punching operation a separate Punching tool is fitted and the job is placed on the die, For riveting operation a riveting head is fitted.

FABRICATION OF PNEUMATIC CONTROLLED RIVETTING AND PUNCHING MACHINE

INTRODUCTION

The press is the punching and riveting machine tool designed to punch letter or rivet metal by applying mechanical force or pressure. The metal is punched or riveted to the desired requirement. The presses are exclusively intended for mass production and they represent the fastest and more efficient way to form a metal into a finished punched or riveted product.

Press tools are used to form and cut thin metals. Press tools operation can be simplified to a few simple operations involving a punch a die. There are Nemours types of presses in engineering field, which are used to fulfil the requirements. We are interested to introduce pneumatic system in presses. The main function of pneumatic press is to form or cut thin sheet metals or non metals using pneumatic power. In this project we have used to punching process and riveting process for simple application.

Principle of Operation of a Press:

Every press has got certain basic units. They are bed frame, sliding ram, drive for the ram and power source. Base or bed is the lower part of the press frame. A thick plate called bolster plate is placed on the top of the bed. A die is fitted on the top of the bolster plate. The driving mechanism is mounted on the frame. The frame has got guide ways for the sliding movement of the ram. The driving mechanism is connected to the ram. The punch is fitted at the bottom of the ram. The die and punch are correctly aligned. The work piece is in the form of sheet metal. It is fed over the die. When the ram comes down, the punch presses the sheet metal. The required operation is carried out. As said earlier the force from the press is used to do a particular operation. This is done by two main parts die and punch.

WORKING PRINCIPLE:

Compressed air from a compressor is used to press the work by means of the piston and piston rod, cylinder through a lever. The high pressurized air striking against the piston tends to push it upwards. This force is transmitted to a punch by means of a lever by its mechanical advantage. The punch forced downward pierces the work material. This is the main principle of the unit.

Fabricated Pneumatic Jack

1. Mounting Plate
2. Threaded Screw
3. Base Plate
4. Bearing
5. Coupling
6. Movable Joints
7. Steel Plates For Supporting
8. Welding Electrodes
9. Cylinder worming
10. Cylinder stroke

• Motor
• Hardware’s To Fit
• Power Supply
• Switch
• PU fitting
• Teflon tape
• Polyurethane hose
• Riveting mount
• Punching mount

TOOLS USED IN PROJECT:

1. Welding Machine
2. Screw driver
3. Spanner
4. Soldering Rod
5. Soldering flux
6. Cutter
7. Lathe
8. Knurling Tool
9. Tapper Tool
10. Machine Vice
11. Axe Frame

Design And Development of Air Caster -Mechanical Project

November 11, 2016, 8:27 am

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Design And Development of Air Caster -Mechanical Project

Air Caster:

An air caster is a pneumatic lifting device used to move heavy loads on flat, non-porous surfaces. Its operation is similar to a hovercraft, as it uses a thin layer of air as a way to float a very small distance off the ground. Compressed air enters an airbag shaped like a torus, and when the bag is filled it creates an airtight seal with the ground, and forces more air into the center of torus, eventually causing the air to flow over the bag and to raise the load above the ground.

The compressed air is forced under the airbag, pushing it and the load less than a millimeter off the ground.

Abstract:-

Material handling equipment are widely used in industry to handle the heavy process equipment’s like boiler, end shield and for movement of heavy materials and machineries.

This dissertation work contributes for the development of a material handling equipment, which is use for movement of heavy loads so, for this application, air caster is designed because of its feature like easily movable heavy loads and positional accuracy in movement.

The present work includes design and modeling of 100kg air caster. The components of air caster like

base plate, load landing plate form, air bag, supporting rings. The selection of the sub components like connectors, nipples, hose pipe, elbows, five way air junction, fasteners are taken standard.

Also 3D components and assembly drawing of air caster have been prepared by using auto desk inventor software.

Design And Development of Air Caster

Problem Definition

1. To develop a flexible material handling equipment for movement of the heavy loads by the application of small effort
2. To develop such material handling equipment which does not damage the floor.
3. To carried out the design, part modeling and development of 100kg air caster.

Working principle :

Stage-1 Air filling

Working Of Air caster

Stage-2 Air bag inflation

Working Of Air caster

Stage-3 Air Escapes and Air film formation

Working Of Air caster

Design Of Air Caster:

The general procedure to solve a design problem is as follows:

1. Need of Air Caster

The air caster is selected for specific job movement application is due to the following reason.

Not availability of crane.

Low floor loading

Least cost movement.

Omni directional movement can achieve.

2. Job Parameters.

Weight -100 kg (gross weight)

Job size - less then 1000x1000mm.

CONCLUSION

•After following design procedure we got system parameters as……….

Pressure requirement :- 13psi

Base plate:- 1000 x1000x5mm

Load landing platform:-1000x1000x12mm

Centre plate:- dia75mm

Supporting ring:- dia 250mm internal

Ø310mm outer

Air escaping holes in air bag:-dia 1.97mm

Fasteners:- M6 and M8

Elbows, hose pipe, air conveying pipe:-3/8 inch

•As the system is designed for 100kg’s(gross),but after taking performance trial we

got that the system can efficiently works even with 120kg’s(gross).